Fluid routing system for indoor grow facilities

ABSTRACT

A fluid routing system for use in an indoor grow facility includes a plurality of supply lines, and a plurality of frames aligned in series and spaced apart from each other. Each of the frames includes a plurality of support openings. Each of the support openings is sized to receive and retain a corresponding one of the supply lines.

BACKGROUND

The field of the disclosure relates generally to indoor grow facilitiesand, more particularly, to systems for fluid circulation to plants ingreenhouses and other indoor grow facilities.

At least some known indoor grow facilities, such as greenhouses, includeair handling systems for circulating conditioned or recycled air toplants housed therein, and watering systems for circulating water,including nutrient-enriched water, to the plants. Moreover, at leastsome known indoor grow facilities include additional supply systems,such as carbon dioxide supply systems for routing supplemental carbondioxide to the plants. In addition, at least some industrial greenhousesare as large as 45,000 square feet and new indoor grow facilities maycontinue to grow in size, resulting in a need for correspondinglylengthy supply lines routed to plants throughout the facility.

The various supply systems in at least some known indoor grow facilitiesare implemented separately from each other, resulting in ad hoc routingof supply lines and, often, unintended interference or entanglementamong the supply lines or other components of the various systems. Atleast some known indoor grow facilities consequently experienceinefficient use of potential grow space within the facility, difficultyin re-routing supply lines to accommodate reorganization of the growspace, and/or difficulty in re-configuring one or more of the supplysystems without requiring shutdown or re-work of the other systems aswell. Moreover, at least some known air handling systems for circulatingconditioned or recycled air are configured for installation adjacent toa ceiling of the facility, and/or are sized to condition the airthroughout an entire floor-to-ceiling space of the facility, increasingboth an initial cost and a maintenance cost of the systems.

BRIEF DESCRIPTION

In one aspect, a fluid routing system for use in an indoor grow facilityis provided. The routing system includes a plurality of supply lines,and a plurality of frames aligned in series and spaced apart from eachother. Each of the frames includes a plurality of support openings. Eachof the support openings is sized to receive and retain a correspondingone of the supply lines.

In another aspect, a fluid routing system for use in an indoor growfacility is provided. The routing system includes a plurality of framesaligned in series and spaced apart from each other. Each of the framesincludes a plurality of support openings. The routing system alsoincludes an air line retained in a first of the plurality of supportopenings of each of the frames, and a drip feed line retained in asecond of the plurality of support openings of each of the frames.

Various refinements exist of the features noted in relation to theabove-mentioned aspects of the present disclosure. Further features mayalso be incorporated in the above-mentioned aspects of the presentdisclosure as well. These refinements and additional features may existindividually or in any combination. For instance, various featuresdiscussed below in relation to any of the illustrated embodiments of thepresent disclosure may be incorporated into any of the above-describedaspects of the present disclosure, alone or in any combination.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevation view of an example greenhouse air andnutrient routing system.

FIG. 2 is a top view of the routing system of FIG. 1 having plantspositioned on opposing sides of the routing system.

FIG. 3 is a front view of an example routing system frame.

FIG. 4 is a sectional view of the routing system frame taken along line“4-4” in FIG. 3.

FIG. 5 is a front view of another example routing system frame.

FIG. 6 is a sectional view of the routing system frame of FIG. 5, takenalong line “6-6” in FIG. 5.

Corresponding reference characters indicate corresponding partsthroughout the drawings.

DETAILED DESCRIPTION

FIG. 1 is a side elevation view of an example fluid routing system 100(hereinafter referred to as the “routing system”) for use in an indoorgrow facility, such as a greenhouse. FIG. 2 is a top view of the routingsystem 100 having plants 190 positioned on opposing sides of the routingsystem 100. The routing system includes a plurality of frames 120aligned in series and spaced apart from each other by a longitudinaldistance 122. The frames 120 cooperate to support a plurality of supplylines 130. In the illustrated embodiment, each adjacent pair of frames120 is spaced apart by a substantially equal longitudinal distance 122.In alternative embodiments, the longitudinal distance 122 varies betweenat least some pairs of adjacent frames 120. For example, but not by wayof limitation, the longitudinal distance 122 is between three and eightfeet. In some embodiments, the supply lines 130 are between about 50feet and about 150 feet in length, and the plurality of frames 120 arespaced in series along the length of the supply lines 130 at thelongitudinal distance 122 of about 5 feet. Although only three frames120 are shown arranged longitudinally in FIG. 1, it should be understoodthat any suitable number of frames 120 is arranged longitudinally toaccommodate a longitudinal length of the row of plants 190. Moreover,although the frames 120 are shown aligned along a straight line in FIG.1, it should be understood that the frames 120 may be aligned in seriesalong any suitable curvilinear path of the supply lines 130.

In the illustrated embodiment, each frame 120 is substantially identicalto the other frames 120, such that each frame 120 is interchangeablyusable during installation, repair, and/or reconfiguration of therouting system 100. In alternative embodiments, at least one frame 120is other than substantially identical to others of frames 120. Eachframe 120 includes a plurality of support openings 310 (shown in FIGS. 3and 5) each sized to receive and retain a corresponding supply line 130.

In the illustrated embodiment, the routing system 100 includes at leastthree supply lines 130. More specifically, a first supply line 130,designated as air line 140, is fluidly coupled to an air source 144. Insome embodiments, the air source 144 is an HVAC system that conditionsat least one of a temperature and a humidity of the air supplied to airline 140. In other embodiments, the air source 144 is a fan, forexample, that supplies air recycled from another location within oroutside the indoor grow facility.

In the illustrated embodiment, the air line 140 includes a plurality ofapertures 142 configured to supply air from within air line 140 toplants 190 adjacent to the routing system 100. For example, but not byway of limitation, the apertures 142 are slots formed through a sidewallof the air line 140. In the illustrated embodiment, the apertures 142are distributed longitudinally along the air line 140 and on opposinglateral sides of the air line 140 to provide a steady supply of air toplants 190 on either side of the routing system 100 along a length ofthe routing system 100. In alternative embodiments, the apertures 142are formed and arranged in any suitable fashion that enables the airline 140 to function as described herein.

In the illustrated embodiment, a second supply line 130, designated asdrip feed line 150, is fluidly coupled to a liquid plant feed source154. For example, but not by way of limitation, the liquid plant feedincludes water enriched with suitable nutrients tailored to improve thegrow of the plants 190 positioned adjacent to the routing system 100.More specifically, in the illustrated embodiment, the second supply line130 includes a pair of drip feed lines 150 extending in parallel onopposing lateral sides of frames 120. In alternative embodiments, thesecond supply line 130 includes any suitable number of drip feed lines150.

Each drip feed line 150 includes a plurality of drip feed outlets 152configured to supply liquid plant feed from within the respective dripfeed line 150 to plants 190 adjacent to the corresponding lateral sidesof the routing system 100. For example, but not by way of limitation,the outlets 152 are nozzles coupled to a sidewall of drip feed line 152and oriented to direct liquid plant feed from within the drip feed line150 towards the bases of the plants 190 adjacent to the routing system100. In the illustrated embodiment, the outlets 152 are distributedlongitudinally along each drip feed line 150 and oriented downward andpartially laterally outward from the frames 120 to provide a steadysupply of liquid plant feed to the plants 190 along a length of therouting system 100. In alternative embodiments, the outlets 152 areformed and arranged in any suitable fashion that enables the drip feedline 150 to function as described herein.

In the illustrated embodiment, a third supply line 130, designated ascarbon dioxide line 160, is fluidly coupled to a carbon dioxide source164. In the illustrated embodiment, the carbon dioxide line 160 includesa plurality of apertures 162 configured to supply carbon dioxide fromwithin carbon dioxide line 160 to plants 190 adjacent to the routingsystem 100. For example, but not by way of limitation, the apertures 162are slots formed through a sidewall of the carbon dioxide line 160. Inthe illustrated embodiment, the apertures 162 are distributedlongitudinally along the carbon dioxide line 160 and on opposing lateralsides of the carbon dioxide line 160 to provide a steady supply ofcarbon dioxide to the plants 190 on either side of the routing system100 along the length of the routing system 100. In alternativeembodiments, the apertures 162 are formed and arranged in any suitablefashion that enables the carbon dioxide line 160 to function asdescribed herein. In certain embodiments, the use of a separate carbondioxide line 160, rather than for example adjusting carbon dioxidecontent within air line 140, facilitates improved tuning of an amount ofcarbon dioxide delivered to the plants 190.

In other embodiments, the routing system 100 includes any suitablenumber of additional or alternative supply lines 130 as is suitable forplants 190.

In the illustrated embodiment, the routing system 100 further includes asupport surface 110 configured to support the frames 120 in relation tothe plants 190. For example, but not by way of limitation, the supportsurface 100 is a table sized to position the drip feed outlets 152 alongthe sides of the routing system 100 directly above the bases of therespective rows of plants 190 on opposing sides of the routing system100, and/or to position air and carbon dioxide apertures 142, 162directly adjacent to the leaves of the plants 190. In alternativeembodiments, the support surface 110 is any suitable support surfacethat enables the routing system 100 to function as described herein.

In the illustrated embodiment, the routing system 100 further includes aplurality of connectors 180 configured to secure the frames 120 to thesupport surface 110. For example, the support surface 110 defines a topface 112, an opposite bottom face 114, and at least one slot 116 thatextends through the support surface 110 from the top face 112 to thebottom face 114. More specifically, in the illustrated embodiment, thesupport surface 110 defines two slots 116 adjacent to opposing lateralsides of the support surface 110. Alternatively, the support surface 110defines more or fewer than two slots 116. The connectors 180 extendthrough the slots 116 and through a horizontally oriented flange 370(shown in FIGS. 3 and 5) of the frames 120 to secure the frames 120 tothe support surface 110. Moreover, in some embodiments, the connectors180 are loosened to facilitate sliding the frames 120 and connectors 180along the slots 116 to a desired longitudinal position along the supportsurface 110, and then tightened to re-secure the frames to the supportsurface. In certain embodiments, the connectors 180 are spring-loaded tofacilitate transitioning between such a sliding adjustment mode and asecured condition. In alternative embodiments, the connectors 180 areconfigured to secure the frames 120 to the support surface 110 in anysuitable fashion that enables the routing system 100 to function asdescribed herein. In other alternative embodiments, the routing system100 does not include the connectors 180.

FIG. 3 is a front view of an example routing system frame 120,designated as frame 300, suitable for use with the routing system 100shown in FIGS. 1 and 2. FIG. 4 is a sectional view of the frame 300taken along line 4-4 in FIG. 3. The frame 300 includes a plate portion320 that extends from a first face 301 to an opposite second face 303.The first and second faces 301, 303 are bounded by a plurality of edges306. The plate portion 320 also defines a plurality of support openings310 each extending longitudinally therethrough from the first face 301to the second face 303. Each support opening 310 is sized to receive andretain a corresponding supply line 130 (shown in FIGS. 1 and 2). Becausethe support openings 310 are defined through the plate portion 320, thesupply lines 130 are retained generally within a profile defined by theedges 306 of the plate portion 320, rather than being supported byadditional arms or struts that project outward from the frame 300. Insome embodiments, the frame 300 thus reduces a footprint of the routingsystem 100 and thereby increases a usable grow space in the facility.Additionally or alternatively, the frame 300 thus decreases a safetyrisk posed by inadvertent contact of personnel or other equipment withsuch projections. Additionally or alternatively, the absence of suchadditional arms or struts improves an ease of shipping, storage, andhandling of the frames 300 and assembly of the routing system 100.

In certain embodiments, the plate portion 320 has a thickness 322defined between the first face 301 and the second face 303 of less thanabout 0.25 inches. For example, in the illustrated embodiment, thethickness 322 is about 0.150 inches. In some embodiments, the relativelysmall thickness 322 of the plate portion 320 of frames 300 facilitatesreducing a manufacturing cost of the frames 300. Additionally oralternatively, the relatively small thickness 322 of the plate portion320 facilitates reducing a weight and, thus, increasing an ease ofhandling the frames 300 during installation of the routing system 100 Inalternative embodiments, the plate portion 320 has any suitablethickness 322 that enables the frame 300 to function as describedherein.

In the illustrated embodiment, the plate portion 320 has a generallyrectangular shape. More specifically, the plate portion 320 extendsvertically from a base edge 304 to a top edge 302 over a height L₁, andextends laterally between a pair of lateral edges 308 over a base widthL₂. In alternative embodiments, the plate portion 320 has any suitableshape that enables the frame 300 to function as described herein. Insome embodiments, height L₁ and base width L₂ are each at least about 14inches, providing sufficient stability to the frame 300 whileaccommodating a size of the support openings 310 that corresponds to asize of the supply lines 130 necessary to provide a sufficient flow rateof fluids to the plants 190. In a particular embodiment, the supplylines 130 are between about 50 feet and about 150 feet in length, andthe frames 300 are spaced about 5 feet apart along the length of thesupply lines 130 and have height L₁ and base width L₂ each being about18 inches. In alternative embodiments, height L₁ and base width L₂ eachhave any suitable value that enables the frames 300 to function asdescribed herein. It should be understood that height L₁ and base widthL₂ need not be equal to each other.

With reference to FIGS. 1-4, a first of the plurality of supportopenings 310, designated air support opening 340, is sized to receivethe air line 140 therethrough in a clearance fit. In the illustratedembodiment, the air support opening 340 extends generally through amid-portion of the plate portion 320, such that the air support opening340 is circumferentially closed. Thus, the air support opening 340positions the air line 140 generally midway between the two rows ofplants 190 on opposing lateral sides of the routing system 100,providing an even flow of air to both rows. In alternative embodiments,the air support opening 340 is positioned with respect to the plateportion 320 in any suitable fashion that enables the routing system 100to function as described herein.

In the illustrated embodiment, the air line support opening 340 iscircular to accommodate the air line 140 having a corresponding circularcross-section. In alternative embodiments, the shape of the air supportopening 340 corresponds to any suitable shape of the air line 140. Insome embodiments, the diameter of the air line 140, and thus of the airsupport opening 340, is selected based on the longitudinal length of therow of plants 190 to provide a suitable flow of air to the entire lengthof the row. For example, but not by way of limitation, the air supportopening 340 has a diameter of at least about 7 inches to accommodate arow of plants 190 in a typical indoor grow facility.

In certain embodiments, a ratio of a diameter of the air support opening340 to the base width L₂ of the plate portion 320 is less than about0.80, for example to facilitate stability of the frame 120. For example,in the illustrated embodiment, the ratio of the diameter of the airsupport opening 340 to the base width L₂ of the plate portion 320 isabout 0.68. In alternative embodiments, the ratio of the diameter of theair support opening 340 to the base width L₂ of the plate portion 320 isany suitable value that enables the routing system 100 to function asdescribed herein.

In the illustrated embodiment, a second of the plurality of supportopenings 310, designated drip feed support opening 350, is sized toreceive the drip feed line 150 therethrough in a clearance fit. Morespecifically, in the illustrated embodiment, the second support opening310 includes a pair of drip feed support openings 350 on opposinglateral sides of frame 300 to receive the corresponding pair of dripfeed lines 150. In alternative embodiments, the second supply line 130includes any suitable number of drip feed support openings 350.

In the illustrated embodiment, each drip feed support opening 350 opensto a respective lateral edge 308 of the plate portion 320, such that thedrip feed support opening 350 is circumferentially open. Thus, the dripfeed support opening 350 enables easy removal and replacement of thedrip feed lines 150 from the routing system 100. For example, a numberof the drip feed outlets 152 become clogged after extended usage. Thedrip feed lines 150 are simply changed out, thus avoiding a need to takethe routing system 100 out of service to cleanse and rinse the originaldrip feed lines 150 in situ. For another example, after the routingsystem 100 is used with a first type of plant 190, a different type ofplant 190 with incompatible drip feed nutrient requirements is to benourished by the routing system 100. The drip feed lines 150 are simplychanged out, thus avoiding a need to cleanse and rinse the original dripfeed lines 150 prior to accommodating the different type of plant 190.In alternative embodiments, each drip feed support opening 350 ispositioned with respect to the plate portion 320 in any suitable fashionthat enables the routing system 100 to function as described herein.

In the illustrated embodiment, a third of the plurality of supportopenings 310, designated carbon dioxide support opening 360, is sized toreceive the carbon dioxide feed line 160 therethrough in a clearancefit. In the illustrated embodiment, the carbon dioxide support opening360 opens to the top edge 302 of the plate portion 320, such that thecarbon dioxide support opening 360 is circumferentially open,facilitating easy removal and replacement of the carbon dioxide feedline 160 from the routing system 100, similar to as described above fordrip feed lines 150. More specifically, the carbon dioxide supportopening 360 is positioned generally midway along the top edge 302, andthus generally midway between the two rows of plants 190 on opposinglateral sides of the routing system 100, providing an even flow ofcarbon dioxide to both rows. In alternative embodiments, the carbondioxide support opening 360 is positioned with respect to the plateportion 320 in any suitable fashion that enables the routing system 100to function as described herein.

In the illustrated embodiment, the frame 300 also includes a flange 370extending from at least portions of the edges 306 of the plate portion320. In some embodiments, the flange 370 facilitates an increasedstructural stability of frame 300 in supporting the plurality of supplylines 130. In the illustrated embodiment, the flange 370 is orientedgenerally perpendicular to the plate portion 320. In alternativeembodiments, the flange 370 is oriented in any suitable fashion thatenables the frame 300 to function as described herein. In alternativeembodiments, the frame 300 does not include the flange 370.

In the illustrated embodiment, the flange 370 does not traverse thesupport openings 310 that extend to the edges 306 of the plate portion320, maintaining the ease of insertion and removal of the correspondingsupply lines 130 as described above. In alternative embodiments, theflange 370 traverses at least one of the support openings 310 thatextend to the edges 306.

In the illustrated embodiment, the flange 370 includes a plurality offlange openings 372 defined therein and extending therethrough. In someembodiments, flange openings 372 facilitate securing frame 300 to othersupport structures in the indoor grow facility, such as by accommodatingconnectors. For example, flange openings 372 in flange 370 extendingfrom base edge 304 are sized to receive connectors 180. In alternativeembodiments, the flange 370 does not include flange openings 372.

In some embodiments, the frame 300 is formed from a metal material, suchas but not limited to aluminum. Moreover, in some such embodiments, theframe 300 is unitarily formed from a single piece of sheet metal that ispressed and punched to form the plate portion 320, the flange 370, andthe support openings 310. In certain embodiments, unitary formation ofthe frame 300 from a single sheet of material decreases a manufacturingcost and improves a structural integrity of the frame 300. Inalternative embodiments, the frame 300 is formed from separate pieces ofmetal coupled together, such as by welding.

Alternatively, in some embodiments, the frame 300 is formed from asuitable plastic material, such as via injection molding.

In other alternative embodiments, the frame 300 is formed via anadditive layer manufacturing process (e.g., 3-D printing). For example,a computer aided design (CAD) model of the frame 300 is sliced into aseries of thin, parallel layers, such that a corresponding distributionof material within each sequential layer of the frame 300 is defined. Acomputer numerically controlled (CNC) machine deposits successive layersof material in accordance with the slices of the CAD model and fuses thesuccessive layers together to form the frame 300. The material is, forexample, powdered metal forming a metallic frame 300 or plastic forminga plastic frame 300. Alternatively, any suitable additive manufacturingprocess and material is used.

FIG. 5 is a front view of another example routing system frame 120,designated as frame 500, suitable for use with the routing system 100shown in FIGS. 1 and 2. FIG. 6 is a sectional view of the frame 500taken along line 6-6 in FIG. 5. The frame 500 is substantially identicalto the frame 300 except as otherwise described. In particular, the plateportion 320 of the frame 500 has a generally triangular shape. Morespecifically, the plate portion 320 extends vertically from the baseedge 304 to a top vertex 502 over the height L₁, and extends laterallybetween the pair of lateral edges 308 that taper from a base width L₂ atthe base edge 304 towards a zero width at the vertex 502. In someembodiments, the triangular shape of the plate portion 320 results inrelatively less material needed to make the frame 500, as well as alower center of gravity of the frame 500 and, thus, an increasedstability of the frame 500 against tipping. In alternative embodiments,the plate portion 320 has any suitable shape that enables the frame 500to function as described herein.

In some embodiments, height L₁ and base width L₂ are each at least about14 inches, providing sufficient stability to the frame 500 whileaccommodating a size of the support openings 310 that corresponds to asize of the supply lines 130 necessary to provide a sufficient flow rateof fluids to the plants 190. In a particular embodiment, the supplylines 130 are between about 50 feet and about 150 feet in length, andthe frames 500 are spaced about 5 feet apart along the length of thesupply lines 130 and have height L₁ of about 14.5 inches and base widthL₂ of about 18 inches. In alternative embodiments, height L₁ and basewidth L₂ each have any suitable value that enables the frames 500 tofunction as described herein.

Also in contrast to the frame 300, the plate portion 320 of the frame500 defines a pair of carbon dioxide support openings 360 that open tothe respective lateral edges 308. Thus, the frame 500 supports the useof a pair of carbon dioxide supply lines 160 in the routing system 100,rather than a single carbon dioxide supply line.

The frame 500 is formed in substantially identical fashion as thatdescribed above for the frame 300.

The above-described embodiments of fluid routing systems for use inindoor grow facilities overcome at least some disadvantages of knownsystems. In particular, the above-described embodiments consolidatecirculation of conditioned or recycled air, nutrient drip feed, and/orcarbon dioxide along a single path using a consistent framework formedfrom interchangeable frame components. Consolidating these supplysystems reduces their footprint and increases usable growing space. Asone example, with the supply lines consolidated and off of the floor,plants stationed on rolling tables can be successively rolled intoposition adjacent to the stationary routing system to cycle a largenumber of plants through nutrient sessions. Additionally, providing thecarried fluids, including air, directly to plants and plant basesimproves plant health while reducing or eliminating a need for costlyoverhead air handling/circulation apparatus, and reducing required airhandling tonnage. The embodiments therefore add efficiency and space toindoor grow facilities, reduce costs associated with operation, andfacilitate healthier plant growth.

Example embodiments of greenhouse air and nutrient routing systems aredescribed above in detail. The greenhouse air and nutrient routingsystems are not limited to the specific embodiments described herein,but rather, components of the greenhouse air and nutrient routingsystems may be used independently and separately from other componentsdescribed herein. For example, the routing system frames describedherein may be used with a variety of plant growth operations, includingand without limitation, large scale and small scale outdoor plantgrowing operations, public and private gardens, and other growfacilities. Embodiments disclosed enable efficient distribution of fluidnutrients to plants without requiring significant modifications to othercomponents of a greenhouse or other plant growth operation. Thus, thedisclosed volutes may be readily incorporated into existing greenhouseor other plant growth operation designs.

As used herein, the terms “about,” “substantially,” “essentially” and“approximately” when used in conjunction with ranges of dimensions,concentrations, temperatures or other physical or chemical properties orcharacteristics is meant to cover variations that may exist in the upperand/or lower limits of the ranges of the properties or characteristics,including, for example, variations resulting from rounding, measurementmethodology or other statistical variation. Additionally, unlessotherwise indicated, the terms “first,” “second,” etc. are used hereinmerely as labels, and are not intended to impose ordinal, positional, orhierarchical requirements on the items to which these terms refer.Moreover, reference to, for example, a “second” item does not require orpreclude the existence of, for example, a “first” or lower-numbered itemor a “third” or higher-numbered item.

When introducing elements of the present disclosure or the embodiment(s)thereof, the articles “a”, “an”, “the” and “said” are intended to meanthat there are one or more of the elements. The terms “comprising,”“including,” “containing” and “having” are intended to be inclusive andmean that there may be additional elements other than the listedelements. The use of terms indicating a particular orientation (e.g.,“top”, “bottom”, “side”, etc.) is for convenience of description anddoes not require any particular orientation of the item described.

As various changes could be made in the above constructions and methodswithout departing from the scope of the disclosure, it is intended thatall matter contained in the above description and shown in theaccompanying drawing[s] shall be interpreted as illustrative and not ina limiting sense.

What is claimed is:
 1. A fluid routing system for use in an indoor growfacility, said routing system comprising: a plurality of supply lines;and a plurality of frames aligned in series and spaced apart from eachother, each of said frames comprising a plurality of support openings,each of said support openings sized to receive and retain acorresponding one of said supply lines.
 2. The routing system of claim1, wherein said frames are substantially identical to each other.
 3. Therouting system of claim 1, wherein each of said frames comprises a plateportion that extends from a first face to an opposite second face, saidfirst and second faces being bounded by a plurality of edges.
 4. Therouting system of claim 3, wherein said supply lines are retained withina profile defined by said edges.
 5. The routing system of claim 3,wherein said plate portion has a shape that is generally one ofrectangular and triangular.
 6. The routing system of claim 3, whereinsaid plate portion defines said plurality of support openings eachextending longitudinally therethrough from said first face to saidsecond face.
 7. The routing system of claim 6, wherein a first of saidsupport openings extends through a mid-portion of said plate portion,such that said first support opening is circumferentially closed.
 8. Therouting system of claim 7, wherein a second of said support openingsopens to one of said edges of said plate portion.
 9. The routing systemof claim 3, wherein each of said frames further comprises a flangeextending from at least portions of said edges of said plate portion.10. The routing system of claim 9, wherein said flange comprises aflange opening defined therein and extending therethrough, said routingsystem further comprising a connector received through said flangeopening and securing said frame to a support surface.
 11. A fluidrouting system for use in an indoor grow facility, said routing systemcomprising: a plurality of frames aligned in series and spaced apartfrom each other, each of said frames comprising a plurality of supportopenings; an air line retained in a first of said plurality of supportopenings of each of said frames; and a drip feed line retained in asecond of said plurality of support openings of each of said frames. 12.The routing system of claim 11, further comprising a carbon dioxide lineretained in a third of said plurality of support openings of each ofsaid frames.
 13. The routing system of claim 11, wherein said second ofsaid plurality of support openings comprises a pair of support openingson opposing lateral sides of said frame, and said drip feed linecomprises a pair of drip feed lines retained respectively in said pairof support openings.
 14. The routing system of claim 11, wherein saidframes are substantially identical to each other.
 15. The routing systemof claim 11, wherein each of said frames comprises a plate portion thatextends from a first face to an opposite second face, said first andsecond faces being bounded by a plurality of edges.
 16. The routingsystem of claim 15, wherein said air line and said drip feed line areretained within a profile defined by said edges.
 17. The routing systemof claim 15, wherein said first support opening extends through amid-portion of said plate portion, such that said first support openingis circumferentially closed, and said second support opening opens toone of said edges of said plate portion.
 18. The routing system of claim15, further comprising a carbon dioxide line retained in a third of saidplurality of support openings of each of said frames, wherein saidsecond support opening opens to a lateral edge of said edges of saidplate portion and said third support opening opens to a top edge of saidedges of said plate portion.
 19. The routing system of claim 15, furthercomprising a carbon dioxide line retained in a third of said pluralityof support openings of each of said frames, wherein said second supportopening and said third support opening each open to a lateral edge ofsaid edges of said plate portion.
 20. The routing system of claim 11,wherein each of said frames further comprises a flange extending from atleast portions of said edges of said plate portion.